Nickel-iron battery with a chemically pre-formed (cpf) iron negative electrode

ABSTRACT

Provided is a Ni—Fe battery comprising an iron electrode which is preconditioned prior to any charge-discharge cycle. The preconditioned iron electrode used in the Ni—Fe battery is prepared by first fabricating an electrode comprising an iron active material, and then treating the surface of the electrode with an oxidant to thereby create an oxidized surface.

RELATED APPLICATIONS

This application is a continuation of U.S. non-provisional application Ser. No. 14/478,896 filed Sep. 5, 2014 which claimed priority to provisional applications U.S. 61/874,177 filed on Sep. 5, 2013 and U.S. 61/901,199 filed on Nov. 7, 2013, the contents of all of which are herein incorporated by reference in their entireties.

BACKGROUND OF THE INVENTION Field of Invention

The present invention is in the technical field of energy storage devices. More particularly, the present invention is in the technical field of rechargeable batteries using iron electrodes.

Related Art

The nickel iron (Ni—Fe) battery was independently developed by Edison in the United States and by Junger in Sweden in 1901. It was industrially important from its introduction until the 1970's when batteries with superior specific energy and energy density replaced Ni—Fe batteries in many applications.

However, Ni—Fe batteries have many advantages over other battery chemistries. The Ni—Fe battery is a very robust battery which is very tolerant of abuse such as overcharge and overdischarge and can have a very long life. It is often used in backup situations where it can be continuously trickle-charged and last more than 20 years. Additionally, the iron active material is much less expensive than active materials used in other alkaline battery systems such as NiMH or in non-aqueous batteries such as Li Ion. However, the low specific energy, low energy density, and poor power have limited the applications of this battery system.

The Ni—Fe battery is a rechargeable battery having a nickel(III) oxy-hydroxide positive electrode and an iron negative electrode, with an alkaline electrolyte such as potassium hydroxide. The overall cell reaction can be written as:

2NiOOH+Fe+2H₂O⇄2Ni(OH)₂+Fe(OH)₂   (1)

Rechargeable batteries often require several charge-discharge cycles prior to achieving optimum performance. During these early cycles, critical surface films are formed on the electrode surfaces that affect the performance of the cell during later cycling. These early cycles are commonly termed formation cycles in the battery industry. In the case of nickel-iron batteries (Ni—Fe), 30 to 60 formation cycles are typically needed to achieve the full capacity of the cell. Formation cycling sometimes requires cycling at varied temperature regimes which complicates the process. This formation process is expensive, time consuming, consumes electrolyte which needs replacing, and generates a significant amount of gas. Therefore, reducing the number of formation cycles and simplifying the formation process is a worthy goal.

Manohar et. al. in “Understanding the factors affecting the formation of Carbonyl Iron Electrodes in Rechargeable Alkaline Iron Batteries”, J. Electrochem. Soc., 159, 12, (2012) A 2148-2155, reported that one reason for the long formation time could also be the poor wettability of the iron electrode and the inaccessibility of the pores of the iron by the electrolyte. As the pores became more accessible the charge and discharge process produced a progressively rougher surface resulting in an increase in electrochemically active surface area and discharge capacity. Triton X-100, a surfactant, reduced the number of cycles required to achieve higher capacity presumably because it improved access of the electrolyte to the pores.

U.S. Pat. No. 3,507,696 teaches that a mixture of FeO and Fe₂O₃ powders fused with sulfur at 120° C. yields an active material that may be used in an aqueous slurry to impregnate sintered nickel fiber plaques that can used as a negative electrode in a Ni—Fe battery. Several formation cycles are needed to achieve high capacity.

It would be of benefit to the industry to have a battery comprising an iron electrode which is conditioned prior to any charge-discharge cycle so as to minimize the need for formation cycles.

SUMMARY OF THE INVENTION

Provided is a nickel-iron (Ni—Fe) battery which comprises a chemically pre-formed (CPF) iron negative electrode. The CPF iron electrode is prepared by:

-   i) fabricating an electrode comprising an iron active material, and -   ii) treating the surface of the electrode with an oxidant to thereby     create an oxidized surface. In one embodiment, the oxidant comprises     water, hydrogen peroxide, ozone, chlorine, nitric acid,     hypochlorite, nitrous oxide, bromine, iodine, permanganate     compounds, or sodium perborate.

In another embodiment, provided is a nickel-iron battery comprised of an electrode which comprises an iron active material, and which electrode has been preconditioned prior to any charge-discharge cycle to have the accessible surface of the iron material in the same oxidation state as discharged iron negative electrode active material. In one embodiment, the oxidation state of the conditioned iron active material is +2, +2/+3, +3 or +4.

Among other factors, the present invention provides a nickel-iron battery which contains a CPF iron anode, i.e., an iron anode conditioned prior to any charge-discharge cycle. The employment of this iron anode in the Ni—Fe battery addresses the mismatch in the state-of-charge (SOC) of the anode and cathode that is present during Ni—Fe cell assembly. Use of the present iron electrode in the Ni—Fe battery decreases the number of cycles, and time to achieve cell formation, electrolyte consumption, hydrogen gas generated, and the amount of water needed to refill the cell. In general, the use leads to improved iron utilization in the battery.

BRIEF DESCRIPTION OF THE FIGURES OF THE DRAWING

FIG. 1 is an illustration of the interparticle contact between active material particles and the space between particles or pores that can be filled with an oxident to precondition the surface of the electrode particles.

FIG. 2 shows the capacity of Ni—Fe cells with and without preconditioned iron electrodes.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention comprises an improved Ni—Fe battery employing a chemically preconditioned iron electrode. In one embodiment, the iron electrode is comprised of a single conductive substrate coated with iron active material on one or both sides. The battery may be prepared by conventional processing and construction employing a nickel oxyhydroxide positive electrode, an alkaline electrolyte, and separator. The nickel electrode may be of a sintered type well known in the art or may be of a pasted type employing a foam or felt matrix. In one embodiment, the separator is a polyolefin material. The battery electrolyte may comprise of a KOH solution or alternatively be a NaOH based electrolyte.

The chemically preconditioned iron electrode used in the NiFe battery of the present invention is prepared by chemically treating an iron metal electrode after the electrode is assembled to provide a preconditioned iron electrode. The preconditioned electrode may be prepared from a standard iron electrode used in Ni—Fe cells. These iron electrodes can be comprised of iron particles or mixtures thereof with sulfur, nickel, or other metal powders, bonded to a substrate. In one embodiment, a conductive additive for the iron electrode comprises nickel, carbon black or copper. In one embodiment, an additive of the iron electrode comprises sulfur. In another embodiment, the coating of active material of the iron electrode comprises a binder for the iron or iron active material, and additives. The binder is generally a polymer such as PVA, or a rubber. The use of a PVA binder has been found to be quite beneficial and advantageous.

In one embodiment, the iron electrode comprises about 50-90 wt % iron powder, and in another embodiment from about 75-85 wt % iron powder; from about 5-30 wt % nickel powder, and in another embodiment from about 12-20 wt % nickel powder; from 0.5-5.0 wt % binder, and in another embodiment from about 2.0-5.0 wt % binder; and, from 0.25-2.0 wt % sulfur, and in another embodiment, from about 0.25-1.0 wt % sulfur. In one embodiment, the iron electrode comprises about 80 wt % iron powder, about 16 wt % nickel powder, about 3.5 wt % binder and about 0.5 wt % sulfur powder.

In one embodiment, the iron electrode can comprise additional conventional additives, such as pore formers. In general, the porosity of the iron electrode is in the range of from 15-50%, and in one embodiment from 35-45%.

The substrate used in the electrode can be comprised of a conductive material such as carbon or metal. The substrate for the iron electrode is generally a single layer of a conductive substrate coated on at least one side with a coating comprising the iron active material. Both sides of the substrate can be coated. In one embodiment, the coating on at least one side comprises iron and additives comprised of sulfur, antimony, selenium, tellurium, nickel, bismuth, tin, or a mixture thereof. The substrate is generally a metal foil, metal sheet, metal foam, metal mesh, woven metal or expanded metal. In one embodiment, the substrate for the iron electrode is comprised of a nickel plated steel. It is generally of porous construction such as that provided by a mesh, or grid of fibrous strands, or a perforated metal sheet. The iron electrode can also be sintered.

The iron electrodes of the present invention are chemically preconditioned with oxidants that are able to oxidize the iron surface. These materials include but are not limited to: water, hydrogen peroxide, ozone, chlorine, nitric acid, hypochlorite, nitrous oxide, bromine, iodine, permanganate compounds, and sodium perborate. Oxidizing materials that are non-toxic and volatile and yield reduction or thermal decomposition products that are also non-toxic and volatile are preferred. Preferred oxidants are water and hydrogen peroxide. Water and solutions used to pretreat the iron electrodes may or may not contain a surfactant. An example of a surfactant that may be used includes but is not limited to Triton X-100. The treatment of the electrodes may be accomplished by coating, dipping, spraying, or otherwise applying oxidants or solutions containing the oxidant to the electrode. The electrode may also be preconditioned by exposing the electrode to an oxidizing gas. The electrode may be rinsed with water after preconditioning with the oxidant to remove the reduced form of the oxidant such as chloride. After rinsing, the electrode is then dried.

The length of time the electrodes are treated with the oxidizing gas can vary, but is generally until oxidation of the iron on the accessible surface of the electrode is observed. The temperature at which the treatment is made is generally ambient, but it can be at higher temperatures. After the treatment, the electrode can be dried, if needed. It can be air dried or in an oven, for example. This is to make sure all of the oxidizing agent is removed.

In one embodiment, the treatment of the iron electrode is continued until the accessible surface of the iron material of the electrode is in the same oxidation state as the electrode would in the discharged state. This is achieved by the oxidation treatment and can be determined using conventional methods available.

While not wishing to be bound by theory, it is believed that nickel-iron batteries may sometimes be assembled with the nickel cathode (positive electrode) in its discharged state and the iron anode (negative electrode) in its charged state. Thus, when the cell is assembled, there is a mismatch between the state-of-charge (SOC) between the anode and cathode which is corrected during the formation process. During the formation process, it is believed that the low capacity of the early cycles is due to the limited amount of discharge products (ie. Fe(OH)₂, Fe(OH)₃, and Fe₃O₄ depending on depth of discharge) that are formed until the proper conductivity, texture, and porosity of the iron electrode is achieved. Consequently, the negative electrode is in a higher SOC than the positive electrode for most of the formation process.

During the charge of a Ni—Fe cell there are typically two processes that occur at the anode surface, which are shown in Equations 1 and 2 below. Equation 1 is the desired conversion of discharge product, Fe(OH)₂, to iron metal. Equation 2 is the reduction of water to hydroxide and hydrogen gas. The two processes have very similar electrochemical potentials and both are usually active during the charge process.

Fe(OH)₂+2e⁻→Fe+2OH⁻E°=−0.877 V   1

2H₂O+2e⁻→OH⁻E°=−0.828V   2

However, when the negative electrode is at high SOC as in formation, the reaction in Equation 2 is more dominant since there is too little Fe(OH)₂ or other iron compounds with iron in its +2 or +3 oxidation state to accept current from the cathode. The reaction in Equation 2 consumes the water in the electrolyte which needs to be replaced and generates significant amount of gas that can become trapped between the electrodes, further hindering desired electrochemical reactions at the electrode surfaces. Gas generation can cause loss of adhesion of the active material to the electrode further damaging the electrode.

It is believed that chemically pretreating the electrode with oxidants converts areas of the electrode that are accessible by the alkaline electrolyte, including pores, to iron compounds where iron is in its +2 or +3 oxidation state that are capable of being reduced to iron metal when an electrochemical current is applied in a cell. The products of the pretreating of the iron electrode may be the same as the discharge products on the iron electrode, or may be different. With some oxidants, rinsing may be necessary to remove the reduced form of the oxidant and convert the iron salts to iron hydroxides and iron oxides. Following these treatments, the products may comprise independently or as a mixture: Fe(OH)₂, Fe(OH)₃, Fe₃O₄, Fe₂O₃, FeO, and other iron oxides. As a result, the mismatch in the SOC of the anode and cathode that is present during Ni—Fe cell assembly is minimized, if not avoided all together. Use of the present iron electrode thereby decreases the number of cycles and time to achieve cell formation, electrolyte consumption, hydrogen gas generated, and the amount of water needed to refill the cell.

FIG. 1 shows a diagram of an electrode that has been preconditioned. The iron particle active material, 1, retains interparticle contact, 2, and electrical contact between the active materials and the substrate, 3, is maintained. The surface of the electrode and the pores, 4, are able to be contacted by the oxidant for preconditioning. Areas where there is interparticle contact are not oxidized. Because the oxidation products are electrically insulating, it is an advantage of this invention that the areas where there is interparticle contact are not oxidized, maintaining a conductive network between particles.

The present example is provided to further illustrate the present invention. It is not meant to be limiting.

EXAMPLE

An aqueous slurry consisting of 80% iron, 16% nickel, and 0.5% sulfur powders with 3.5% polyvinyl alcohol binder were pasted onto a perforated nickel sheet which was then dried. This sheet was then chemically preconditioned by brushing with deionized water and allowed to dry in air for 16 hours at room temperature followed by drying in an oven at 190° C. for 15 minutes. A 16% weight gain was measured and a slight orange-brown color was observed on the surface of the electrode. Two sample electrodes were cut from this sheet and tabs were TIG welded to the top uncoated area of the electrode. Two sample cells were constructed using these negative electrodes by placing the negative electrode between two commercial Histar sintered positive nickel hydroxide electrodes. Both the positive and negative electrodes were pocketed into a polypropylene separator. For comparison, two identical cells were constructed from identical materials except that the negative electrodes were not chemically preconditioned. The test cells containing CPF iron negative electrodes and the control cells were subjected to an accelerate life test at 55° C. with the following charge regime:

-   -   Cycle 1 (@ Room Temp): Charge: 1.0 A×1.5 hrs         -   Rest: 30 Min         -   Discharge: 0.1 A to 1.0 V         -   Rest: 30 Min     -   Cycle 2-100 (@55° C.): Charge: 1.0 A'1.5 hrs         -   Rest: 30 Min         -   Discharge: 0.1 A to 1.0 V         -   Rest: 30 Min

The cycling characteristics for cells prepared with pre-conditioned iron electrodes is shown in FIG. 2. The cells with chemically pre-conditioned negative electrodes deliver a capacity of 140-160 mAh/g Fe after only five cycles compared to a capacity of 120-135 mAh/g Fe after ten cycles for cells with negative electrodes that were not preconditioned. Furthermore, the overall capacity for cells with preconditioned electrodes is between 17-19% higher for the life of the cell after formation demonstrating a further advantage of this invention.

While the foregoing written description of the invention enables one of ordinary skill to make and use what is considered presently to be the best mode thereof, those of ordinary skill will understand and appreciate the existence of variations, combination, and equivalents of the specific embodiment, method, and examples therein. The invention should therefore not be limited by the above described embodiment, method and examples, but by all embodiments and methods within the scope and spirit of the inventions and the claims appended therein. 

What is claimed is:
 1. A Ni—Fe battery comprising an electrode comprising an iron active material, which electrode has been preconditioned prior to any charge-discharge cycle to have the accessible surface of the iron material in the same oxidation state as discharged iron negative electrode active material.
 2. The battery of claim 1, wherein the oxidation state of the conditioned iron active material is +2, +2/+3, +3 or +4.
 3. The battery of claim 1, wherein the electrode further comprises a binder.
 4. The battery of claim 1, wherein the electrode further comprises sulfur.
 5. The battery of claim 1, wherein the electrode further comprises a conductive additive.
 6. The battery of claim 5, wherein the conductive additive comprises nickel, or copper or carbon black.
 7. The battery of claim 1, wherein the electrode comprises an iron active material comprising about: 50-90 wt % iron powder 5-30 wt % nickel powder 0.5-5.0 w % binder, and 0.25-20 w % sulfur.
 8. The battery of claim 1, wherein the electrode comprise a single layer of conductive substrate coated on at least one side with a coating comprising the iron active material.
 9. The battery of claim 8, wherein the substrate of the electrode is comprised of nickel plated steel.
 10. The battery of claim 1, wherein the porosity of the electrode is in the range of about 15-50%.
 11. A battery of claim 1, wherein the iron electrode is prepared by a process comprising: i) fabricating an electrode comprising an iron active material, and ii) treating the surface of the electrode with an oxidant to thereby create an oxidized surface.
 12. The battery of claim 11, therein the oxidant comprises water, hydrogen peroxide, ozone, chlorine, nitric acid, hypochlorite, nitrous oxide, bromine, iodine, permanganate compounds, or sodium perborate.
 13. The battery of claim 11, wherein the oxidant comprises water or hydrogen peroxide.
 14. The battery of claim 11, wherein the oxidant comprises a gaseous oxidant. 